KR102253782B1 - System for preventing over current flow - Google Patents

Abstract

The present invention relates to an overcurrent inflow prevention system, and more particularly, to an overcurrent inflow prevention system that prevents overcurrent from flowing in reverse connection by connecting a photo relay to a gate terminal and a source terminal of a discharge switch.

Description

Overcurrent inflow prevention system{SYSTEM FOR PREVENTING OVER CURRENT FLOW}

The present invention relates to an overcurrent inflow prevention system, and more particularly, to an overcurrent inflow prevention system that prevents overcurrent from flowing in reverse connection by connecting a photo relay to a gate terminal and a source terminal of a discharge switch.

With the development of the industry, the demand for electric power is increasing, and the gap in electric power usage between day and night, seasons, and daily is gradually widening. Recently, for this reason, many technologies for reducing the peak load by utilizing the excess power of the system have been developed rapidly.

A representative of these technologies is an energy storage system (ESS) that stores excess power of the system in a battery or supplies insufficient power of the system from the battery.

The ESS includes an energy generating device, an inverter, a battery and a load.

During normal energy supply, the electric energy generated by the energy generating device is supplied to the load. At the same time, the surplus power of the energy generating device is converted through an inverter, which is a power conversion device, and charged to the battery.

Thereafter, in the case of peak power or a power outage, the power charged in the battery is converted through an inverter and supplied to the load.

On the other hand, when the inverter and the battery are connected in such an ESS configuration, a danger situation may occur where a large current momentarily flows by incorrectly connecting the (+) and (-) terminals.

In general, in order to prevent the inflow of overcurrent, a protection circuit and a protection fuse are configured in the battery to protect the current of the battery by turning it on/off. When overcurrent flows, the protection fuse is melted or the switch in the protection circuit is turned off to turn off the battery. Protect.

However, since the protection circuit configuration is controlled through the BMS, the response speed is slower than that of the protection fuse, and once the protection fuse is melted, there is a trouble of replacing it.

Therefore, the reverse connection as described above is the simplest to form the shape of each of the (+) and (-) terminals different from the current O-ring type, but the connection terminal is changed according to the user. In the case of changing, the production cost increases and a problem arises that the produced product cannot be used universally.

Therefore, it is required to develop a technology to improve the versatility of the product by forming a different terminal shape or by forming a separate configuration on the system rather than using a BMS, and to quickly prevent the inflow of overcurrent generated during reverse connection.

KR 2012-0096217 A

The present invention provides an overcurrent inflow prevention system that prevents inflow of overcurrent generated when a terminal is reversely connected.

In the overcurrent inflow prevention system according to an embodiment of the present invention, in the overcurrent inflow prevention system for preventing the inflow of overcurrent when power is reversely connected, a discharge switch unit and a first side are connected to a gate terminal in the discharge switch unit, and a second side is discharged. It is connected to the source terminal in the switch unit, the third side is connected to the battery (-) side forming an overcurrent inflow path when the power is reversely connected, and the fourth side includes an overcurrent inflow prevention circuit unit connected to the battery (+) side. When the overcurrent flows through the third side of the overcurrent inflow prevention circuit unit, the first side and the second side of the overcurrent inflow prevention circuit unit are connected to each other, and the discharge switch unit is short-circuited.

An overcurrent protection resistor is disposed on the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit part.

The overcurrent inflow prevention circuit unit includes a photo relay.

The photo relay includes a diode connected in a forward direction in a direction from a third side to a fourth side of the overcurrent inflow prevention circuit part.

The photo relay is connected to the first side and the second side of the overcurrent inflow prevention circuit part, and is turned on when a predetermined voltage value or more is applied through the diode, thereby electrically connecting the first side and the second side. It consists of a switching unit.

The overcurrent inflow prevention circuit unit is configured to further include a notification unit for transmitting a reverse connection signal to the BMS that controls the on/off of the discharge switch unit when the photo relay is turned on.

The BMS, which has received the reverse access signal from the notification unit, transmits the reverse access signal to a separate display device mounted outside the battery.

In the method of configuring an overcurrent inflow prevention system according to an embodiment of the present invention, in a method of configuring an overcurrent inflow prevention system that prevents overcurrent inflow when a power source is reversely connected, a voltage measurement step of measuring a voltage value of an inflow overcurrent when power is reversely connected. , The minimum resistance value calculation step of calculating the minimum value of the overcurrent protection resistor based on the voltage value measured in the voltage measurement step, a predetermined voltage that turns on the photo relay when overcurrent flows based on the voltage in the battery during discharge. A resistor that sets a reference value for selection of an overcurrent protection resistor based on the minimum value of the overcurrent resistance unit calculated in the voltage value setting step for setting a value and the minimum resistance value calculation step, and a predetermined voltage value set in the voltage value setting step It consists of a sub-reference value setting step.

The voltage measurement step is repeatedly performed a predetermined number of times.

In the step of calculating the minimum value of the resistance unit, the highest value of the voltage values measured after repeating a predetermined number of times in the voltage measuring step is used.

The minimum value of the overcurrent protection resistor in the step of calculating the minimum value of the resistance unit is set based on the withstand voltage level of the photo relay.

The overcurrent inflow prevention system according to an embodiment of the present invention provides a quick and fast battery from overcurrent by physically shorting the discharge switch by using a photo relay when overcurrent flows when reverse connection by adding a photo relay to the existing discharge switch. You can protect it safely.

1 is a structural diagram of an overcurrent inflow prevention system according to an embodiment of the present invention.
2 is a flow chart of a method for configuring an overcurrent inflow prevention system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the contents described in the accompanying drawings. However, the present invention is not limited or limited by the embodiments. The only embodiments are provided to complete the disclosure of the present invention, and to fully inform the scope of the invention to those of ordinary skill in the art.

In addition, terms including ordinal numbers such as first and second may be used to describe various elements, but the elements are not limited by the terms. These terms are only used for the purpose of identifying one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element. The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Terms used in the present invention have selected general terms that are currently widely used as possible while taking functions of the present invention into consideration, but this may vary according to the intention or precedent of a technician working in the field, the emergence of new technologies, and the like. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning of the terms will be described in detail in the description of the corresponding invention. Therefore, the terms used in the present invention should be defined based on the meaning of the term and the overall contents of the present invention, not a simple name of the term.

<Example 1>

Next, an overcurrent inflow prevention system according to an embodiment of the present invention will be described.

The overcurrent inflow prevention system of the present invention connects an overcurrent inflow prevention circuit including a photo relay to the gate terminal and the source terminal of the discharge switch to prevent overcurrent from flowing into the battery when power is reversely connected.

1 is a structural diagram of an overcurrent inflow prevention system according to an embodiment of the present invention.

Referring to FIG. 1, in the overcurrent inflow prevention system 100 according to an embodiment of the present invention, a discharge switch unit 110 and a first side are connected to a gate terminal in the discharge switch unit, and a second side is a source in the discharge switch unit. It is connected to the terminal, the third side is connected to the battery (-) side forming an overcurrent inflow path when the power is reversely connected, and the fourth side includes an overcurrent inflow prevention circuit unit 120 connected to the battery (+) side.

Therefore, when the power is reversely connected and the overcurrent flows through the third side of the overcurrent inflow prevention circuit unit 120, the first side and the second side of the overcurrent inflow prevention circuit unit 120 are connected to the discharge switch unit 110. ) Is shorted to prevent overcurrent from flowing into the battery.

This configuration is formed to prevent dangerous situations where large currents and voltages instantaneously flow by incorrectly connecting the (+) and (-) terminals in the process of connecting the inverter and the battery in the ESS configuration.

In addition, in the overcurrent inflow prevention system 100 of the present invention, since the overcurrent prevention control does not go through the BMS, a faster and more immediate response is possible.

Each configuration of the overcurrent inflow prevention system will be described in more detail below.

The discharge switch unit 110 is composed of a FET to turn on/off a discharge current flowing when a load is supplied from the battery.

In addition, the drain terminal of the discharge switch unit 110 is connected to the charging switch unit, and the gate terminal responsible for on/off of the discharge switch unit 110 is the BMS of the battery and the overcurrent inflow prevention circuit unit 120. It is connected to the first side, and the source terminal is connected to the second side of the overcurrent inflow prevention circuit unit 120, and when overcurrent is introduced due to reverse power connection, the first side and the second side are conductive and physically short-circuited. .

As described above, when the discharge switch unit 110 is short-circuited, the state of the discharge switch unit 110 is continuously turned off and on-control is impossible.

Therefore, overcurrent generated due to reverse connection with the battery does not flow into the battery until the inverter reversely connected to the battery is removed.

On the other hand, when the power supply is reversely connected, the (+) voltage of the battery is converted to (-), and the (-) voltage is converted to (+) voltage, so that the structure is converted into a structure as if performing discharge.

Therefore, the overcurrent inflow path is connected to the discharge switch unit 110, not the charge switch unit, so that the discharge switch unit 110 can be used similarly to the case of discharging.

In addition, in the overcurrent inflow prevention circuit unit 120, the first side is connected to the gate terminal in the discharge switch unit, the second side is connected to the source terminal in the discharge switch unit, and the third side connects the overcurrent inflow path when the power is reversely connected. It is connected to the forming battery (-) side, and the fourth side is connected to the battery (+) side.

In addition, an overcurrent protection resistor unit 122 is disposed on an overcurrent inflow path on the third side of the overcurrent inflow prevention circuit unit 120.

If the overcurrent inflow prevention circuit unit 120 is described in more detail, the overcurrent inflow prevention circuit unit 120 includes a photo relay 121, and the photo relay 121 includes the overcurrent inflow prevention circuit unit 120 It includes a diode that can be driven only when current flows from the third side to the fourth side. In short, the diode is connected in a forward direction from the third side to the fourth side of the overcurrent inflow prevention circuit part.

Therefore, when current flows from the fourth side to the third side of the overcurrent inflow prevention circuit unit 120 due to the diode in the photo relay 121, the overcurrent inflow prevention system 100 is not driven.

In addition, the photo relay 121 includes a pair of switching units connected to the gate terminal and the source terminal of the discharge switch unit 110, and is turned on when a predetermined voltage value or more is applied through the diode. And the second side are electrically connected to each other, and the gate terminal and the source terminal of the discharge switch unit 110 are connected to each other.

If the value of the voltage applied through the diode is less than a predetermined voltage value, it is determined that the overcurrent has not been introduced, and the overcurrent inflow prevention circuit unit 120 is not driven, and the current is only (+) from the battery (-) side. Make it flow to the) side.

Here, it is preferable to select a value within 1.5 to 2.5 times the voltage value flowing inside the battery when the battery is discharged.

In addition, the photo relay 121 may be composed of one of a photo MOS relay and a photo coupler. Since the photo MOS relay is non-polar, both AC and DC can be controlled. This long has an advantage.

In addition, since the photo coupler is relatively inexpensive and economical compared to the photo MOS relay, it is efficient to use a photo MOS relay if you want to perform fast overcurrent prevention control, and use a photo coupler if you want to reduce the production cost.

In addition, the overcurrent protection resistor unit 122 is disposed on the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit unit 120 to reduce the voltage of the overcurrent flowing through the overcurrent inflow path.

Here, an overcurrent protection resistor value is set in the overcurrent protection resistor unit 122 to allow a voltage less than the withstand voltage that the photo relay 121 can withstand to flow through the photo relay 121.

In addition, the overcurrent protection resistor unit 122 may be configured with one or more resistors so that excessive heat is not generated from one large resistor.

In addition, when the photo relay 121 is turned on, the overcurrent inflow prevention circuit unit 120 further includes a notification unit for transmitting a reverse connection signal to the BMS that controls the on/off of the discharge switch unit 110 do.

This notification unit is connected to the first side of the overcurrent inflow prevention circuit unit 120 to notify the BMS as soon as the photo relay 121 is turned on.

In addition, the BMS, which has received the reverse connection signal from the notification unit, transmits the reverse connection signal to a separate display device mounted outside the battery so that the user can recognize that the power is reversely connected. Here, the separate display device means a notification sound, an indicator, or a monitor of a server that manages the ESS.

When connecting the battery and the inverter, if the pole of the inverter is reversely connected to the battery, the (+) pole of the battery becomes the (-) pole, and the (-) pole becomes the (+) pole, and overcurrent flows through the power inlet path. Then, the incoming overcurrent passes through the overcurrent protection resistor unit 122.

The overcurrent having a voltage reduced by passing through the overcurrent protection resistor unit 122 enters the third side of the overcurrent inflow prevention circuit unit 120.

The overcurrent turns on a pair of switching units in the photo relay 121 to allow current to flow from the first side to the second side of the overcurrent inflow prevention circuit unit 120.

The current flowing from the first side to the second side of the overcurrent inflow prevention circuit unit 120 flows to the gate terminal and the source terminal of the discharge switch unit 110 so that the discharge switch unit 110 is automatically short-circuited.

When the photo relay 121 is turned on, the notification unit in the overcurrent inflow prevention circuit unit 120 transmits a reverse connection signal to the BMS connected to the discharge switch unit 110.

After receiving the reverse connection signal, the BMS transmits the reverse connection signal again to a separate display device so that the user can be notified of the reverse connection of the inverter.

<Example 2>

Next, a method of configuring an overcurrent inflow prevention system according to an embodiment of the present invention will be described.

The method of configuring an overcurrent inflow prevention system of the present invention is a method of efficiently configuring an overcurrent inflow prevention system by calculating and setting a reference value of each part of the overcurrent inflow prevention system.

2 is a flowchart of a method of configuring an overcurrent inflow prevention system according to an embodiment of the present invention.

Referring to FIG. 2, in the method of configuring an overcurrent inflow prevention system according to an embodiment of the present invention, first, a voltage value of an overcurrent flowing in when the power supply is reversely connected is measured (voltage measurement step: S210), and based on the measured voltage value. A reference minimum value of the overcurrent protection resistor unit 122 is calculated (resistance unit minimum value calculation step: S220).

In addition, a predetermined voltage value for turning on the photo relay 121 is set based on the voltage in the battery during discharge (voltage value setting step: S230), and the overcurrent protection resistance calculated in the minimum resistance value calculation step (S220). The selection reference value of the overcurrent protection resistor unit 122 is set based on the predetermined voltage value set in the minimum value and voltage value setting step S230 of the unit 122 (resistance unit reference value setting step: S240).

As described above, each part of the overcurrent inflow prevention system 100 may be configured based on the value set in each step.

Each step of the method of configuring the overcurrent inflow prevention system will be described in more detail below.

The voltage measurement step (S210) is a step of measuring the voltage value of the overcurrent introduced when the power is reversely connected, and is repeatedly performed a predetermined number of times. Here, the predetermined number is set to 7, as an example, but is not limited thereto.

Thereafter, the highest value among the voltage values measured after repeating a predetermined number of times is set as the value used in the step S220 of calculating the minimum resistance value.

In addition, the voltage value of the overcurrent is measured and the current value is also measured.

In addition, in the step of calculating the minimum resistance value (S220), the minimum value of the overcurrent protection resistor unit 122 is calculated based on the voltage value measured in the voltage measuring step (S210).

Here, the photo relay 121 has a fast on/off response speed and has been previously selected as a component having a high withstand voltage.

The minimum value of the overcurrent protection resistor unit 122 is calculated based on the voltage measured in the voltage measuring step S210 so that a voltage less than the preset voltage level of the photo relay 121 can be applied.

This calculates the minimum value of the overcurrent protection resistor unit 122 by subtracting the maximum voltage value measured in the voltage measuring step S210 by the withstand voltage level of the photo relay 121 and dividing the remaining voltage value with the current value.

For example, when the voltage maximum value in the voltage measurement step (S210) is measured as 10V, the withstand voltage level of the photo relay 121 is 6V and the overcurrent flows at 2A, the overcurrent protection resistor unit 122 The minimum value is calculated as 2Ω. This means that in order for the photo relay 121 to be protected, the overcurrent protection resistor 122 must be set to 2Ω or more.

In addition, the voltage value setting step (S230) is a step of setting a predetermined voltage value for turning on the photo relay 121, and there is a pair of switching units in the photo relay 121 so that a predetermined voltage value or more is It is turned on only when authorized.

Accordingly, the maximum value of the overcurrent protection resistor unit 122 is calculated based on the predetermined voltage value so that the voltage that has passed through the overcurrent protection resistor unit 122 may be greater than or equal to the predetermined voltage value.

Here, it is preferable to select a value within 1.5 to 2.5 times the voltage value flowing inside the battery when the battery is discharged.

The method of calculating the maximum value of the overcurrent protection resistor unit 122 is calculated by dividing the maximum voltage value measured in the voltage measuring step S210 by the predetermined voltage value and decreasing the remaining decimal point.

For example, when the voltage value flowing inside the battery when the battery is discharged is measured as 2V, a predetermined voltage value for turning on the photo relay 121 is set to 3V, and measured in the voltage measuring step (S210). When the maximum voltage value is 10V, the maximum value of the overcurrent protection resistor 122 is calculated as 3Ω so that the photo relay 121 can be turned on. This means that in order for the pair of switching units in the photo relay 121 to be turned on, the overcurrent protection resistor unit 122 must be set to 3Ω or less.

In addition, the resistance reference value setting step (S240) is based on the minimum value of the resistance calculated in the minimum resistance value calculation step (S220) and a predetermined voltage value set in the voltage value setting step (S230), the overcurrent protection resistor unit ( This is the step of setting the selection criterion value of 122).

More precisely, the selection reference value of the overcurrent protection resistor unit 122 based on the maximum value of the overcurrent protection resistor unit 122 calculated based on the predetermined voltage value in the voltage value setting step (S230) Is set.

For example, if the minimum value of the overcurrent protection resistor calculated in the minimum resistance value calculation step (S220) is 2Ω, and the maximum value of the overcurrent protection resistance part calculated in the voltage value setting step (S230) is 3Ω, it is set to 3Ω. Thus, the Port Morse relay can be safely protected.

On the other hand, although the technical idea of the present invention has been described in detail according to the above embodiment, it should be noted that the above embodiment is for the purpose of explanation and not for the limitation thereof. In addition, a person of ordinary skill in the technical field of the present invention may be able to implement various embodiments within the described claims.

100: overcurrent inflow prevention system
110: discharge switch unit
120: overcurrent inflow prevention circuit part
121: photo relay
122: overcurrent protection resistor unit

Claims (11)

In the overcurrent inflow prevention system that prevents overcurrent inflow when power is reversely connected,
A discharge switch unit; And
The first side is connected to the gate terminal in the discharge switch unit, the second side is connected to the source terminal in the discharge switch unit, and the third side is connected to the battery (-) side forming an overcurrent inflow path when power is reversely connected, and the fourth side The side is an overcurrent inflow prevention circuit unit connected to the battery (+) side; Consisting of including,
When the overcurrent flows through the third side of the overcurrent inflow prevention circuit unit, the first side and the second side of the overcurrent inflow prevention circuit unit are connected to each other, and the discharge switch unit is short-circuited.
The method according to claim 1,
An overcurrent inflow prevention system, characterized in that an overcurrent protection resistor is disposed on the overcurrent inflow path of the third side of the overcurrent inflow prevention circuit part.
The method according to claim 1,
The overcurrent inflow prevention circuit unit, overcurrent inflow prevention system, characterized in that configured to include a photo relay.
The method of claim 3,
The photo relay is configured to include a diode connected in a forward direction from a third side to a fourth side of the overcurrent inflow prevention circuit unit.
The method of claim 4,
The photo relay is connected to a first side and a second side of the overcurrent inflow prevention circuit part, and is turned on when a predetermined voltage value or more is applied through the diode to electrically connect the first side and the second side. Overcurrent inflow prevention system, characterized in that configured to include a switching unit.
The method of claim 5,
The overcurrent inflow prevention circuit unit may include a notification unit for transmitting a reverse connection signal to a BMS that controls on/off of the discharge switch unit when the photo relay is turned on; Overcurrent inflow prevention system, characterized in that configured to include an additional. The method of claim 6,
The BMS receiving the reverse connection signal from the notification unit transmits the reverse connection signal to a separate display device mounted outside the battery.
In the method of configuring an overcurrent inflow prevention system that prevents overcurrent inflow when power is reversely connected,
A voltage measurement step of measuring a voltage value of an overcurrent introduced when the power is reversely connected;
A minimum resistance value calculation step of calculating a minimum value of the overcurrent protection resistor based on the voltage value measured in the voltage measurement step;
A voltage value setting step of setting a predetermined voltage value for turning on the photo relay when overcurrent is introduced based on the voltage in the battery during discharge; And
A resistance unit reference value setting step of setting a selection reference value of the overcurrent protection resistor unit based on the minimum value of the overcurrent resistance unit calculated in the resistance unit minimum value calculation step and a predetermined voltage value set at the voltage value setting step;
Overcurrent inflow prevention system configuration method, characterized in that configured to include.
The method of claim 8,
The voltage measuring step is a method for constructing an overcurrent inflow prevention system, characterized in that it repeats a predetermined number of times.
The method of claim 9,
The step of calculating the minimum value of the resistance unit,
The method of constructing an overcurrent inflow prevention system, characterized in that the highest value of voltage values measured after repeating a predetermined number of times in the voltage measurement step is used.
The method of claim 8,
The minimum value of the overcurrent protection resistor in the step of calculating the minimum value of the resistor unit is set based on the withstand voltage level of the photo relay.

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